Lighting control circuits



March 1, 19490 G. c. IZENOUR LIGHTING CONTROL CIRCUITS Filed Aug. 28, 1947 INVENTOR GEORGE C. IZENOUR [/58 A i'forney Patented Mar. 1, 1949 UNITED STATES PATENT ()JFFICE 2,463,463 LIGHTING CONTROL CIRCUITS George C. Izenour, New Haven, Conn. Application August 28, 1947, Serial No. 770,999

31 Claims.

The present invention relates to electrical control circuits for lighting, as in theatres and in television studios.

The currently typical theatre lighting installation has resisted modernization for many years.

It includes a large control panel located backand off-side, where the operator can View A few rheostats can be coupled for Joint.mechanicalcontrol; but when so conequipment is a major undertaking.

There have been a few attempts at remote control of stage lighting, in order to get the operator out front with the audience for a direct view of the performance. This has been accomplished Another remote-controlled lighting control syssaturable reactors, where controlled direct current determines the saturation of the cores in the reactors; and these variably reduce the voltage supplied to the lamps efficiently, without significant power loss except for the direct current in the control circuits.

ever a very significant power loss avoidance is accompanied by a, very significant time lag introduced between the change of control and the change ,of efiect, loads that require large reactors.

reactors are inflexible, ,in that they must. be used withloads of definite sizes, within a limited range, to be effective; and they are massive.

this background my invention will equipment for producingmore varied dramatic and artistic efifects, so characteristically compact that increased control of the system become relatively simple operations.

A further aim is to provide a control system to enable even an unskilled operator to control many lighting banks in a sequence of scenes with predetermined intensity schedules, from one perestablished during rehearsal, and later unfailingly reproduced promptly and without experimentation during carefully timed broadcasts.

From the foregoing and from the following detailed will be described in detail,

The drawing is the wiring diagram of the presently preferred embodiment of the invention, showing only two lamps and heir control circuits, but indicating the manner of extension to numerous separate, optionally correlated lamp and control circuits. Incandescent lamps l and Ill are energized by opposite halves of step-up autotransformer 12 through back-to-back thyratrons 14, I5 and l4, l6, respectively. Each of these lighting circuits is connected between a bright bus l8 or ill and a neutral bus or ground (shown throughout the diagram as a darker line). The autotransformer divides the line voltage to provide a neutral with a roughly balanced load on each side. Autotransformer l2 boosts the resulting divisions of the line voltage to compensate for the internal voltage drop in the thyratrons and the autotransformer itself so that lamps of standard voltage ratings can be used. Thyratrons are chosen for moderate loads, and this term is intended to represent any appropriate grid-controlled gas-type electron-discharge devices generally. Each pair of thyratrons provides independent control for its series lamp, although it will appear that coordinating controls are also available. Each lamp Hi and if) is representa tive of a single lamp or a lighting bank that optionally includes many lamps, up to the current limit of the thyratrons.

Under proper conditions of grid excitation each thyratron can be made conductive during substantially an entire half of an alternating-current cycle. 1 The pairs of thyratrons, because of their back to-backconnection, can supply lamp current throughout the alternating current cycle when maximum intensity is desired. By properly adjusting the grid excitation of the thyratrons the firing of each can be retarded, for lower light intensities. A change of this adjustment is instantly followed by a change in light intensity, for no heavy iron-cored inductor is included in the lamp circuit.

The thyratron grids are here supplied with alternating current, and their control effect is attained by controlling the phase of the grid drive in relation to the plate alternating current supply. Where the grid voltage is in phase with the plate supply or somewhat leading, the thyratron plates will be conductive during substantially completehali-cycles because the instantaneous grid voltage will be positive at the start of the positive half-cycles of the plate. By applying lagging voltage between the thyratron grids and cathodes, the firingof the thyratrons can be delayed during each half-cycle, since the grid voltage remains negative during the elapsing first part of each positive half-cycle of the plate. By controlling the phase of the grid voltage, the timedivision during which current is supplied to the lamps can be varied to change the effective current, although the instantaneous current during'the conductive intervals may not vary significantly. In this way the energy supplied to the lamps from fixed-voltage lines is efficiently varied, without the large power waste characteristic of the series resistors so commonly used in lighting control.

The grid-supply circuit of thyratrons l4 and I6 that of thyratrons l4 and 16' being in most respects identical as will be understood from the primed numerals on like parts. The thyratron grid supply includes a pair of back-to-back vacuum-tube sections 22 and 24 connected in series with condenser 26 across the --same buses I8 and 20 that supply the thyratronlamp circuit. Sections 22 and 24 are enclosed in a common envelope for convenience only; they may readily be replaced by separate vacuum tubes, and will therefore be treated as separate tubes. Tubes 22 and 24 together pass alternating current and represent a resistance the magnitude of which deuends on the grid drive. A pair of resistors 28 and 36 are also connected across buses l8 and 20, the junction of the resistors furnishing a voltage reference point. The primary winding 36 of thyratron grid transformer 32 is connected between the junction of these resistors and the junction 36 of the condenser 26 and vacuum tubes 22, 24. (A trimmer resistor is sometimes desirable between condenser 26 and junction 36; so that the latter does not necessarily exist as a tube-condenser junction). Separate secondaries t3 and 3860 are connected between the respective grids and cathodes of thyratrons l4 and [6, through the usual grid current limiting resistors.

In successive half-cycles the thyratron grids are alternately energized to fire their respective plate-circuits. When the plate of one thyratron is negative, its grid voltage is of no concern; for the voltage on the grid of the associated thyratron will control the time of firing of that thyratron during the positive half-cycle of its plate. In the subsequent half-cycle the plate polarities are reversed, and at the same time the grid control voltage is reversed, to establish the desired control relation in the previously idle thyratron. Condenser Z6 and vacuum tubes 22, 24 provide full-wave drive of controlled phase to the thyratron grids.

The full-cycle control by the thyratrons over the lamp circuit reduces the required current rating of each and promotes superior lightingcontrol and line-loading conditions. This fullcycle control utilizes the full-cycle symmetry provided by the back-to-back vacuum-tube phase control network.

In firing, each thyratron suddenly imposes a load on the line. Many lighting loads may be assembled in any given scene, with certain of them operating at different intensities. Because of this, there may be disturbances in line voltage caused by early-firing thyratrons that have some unplanned effect on the control circuits of the later-to-be-fired thyratrons. tending to produce flickering. To minimize the efiect of line-voltage transients caused by other lighting circuits and be miscellaneous loads, and partly for added flexibility of the control equipment, I have found that excellent stability of control can be realized through supplying full-wave rectified alternating current to the grids of vacuum tubes 22 and 24. The reason for improved flexibility will become clear as the disclosure continues.

The grids of vacuum tubes 22 and 24 are connected to the negative output terminals of selenium dry-disc full-wave rectifiers 40 and 4'2, energized by secondaries M and 46 of transformer 43, the center-taps of the secondaries being connected to the respective cathodes of vacuum tubes 22 and 24. By controlling the amplitude of voltage supplied to grid transformer 48 the plate resistance of tubes 22 and 24 can be varied widely, as by driving the tubes to cut-off for maximum resistance or by minimizing the supplied voltage, for minimum plate resistance. As the resistance changes from minimum to maximum the phase of the voltage at point 36 varies through almost degrees. This provides economically and simply for adequate phase-control of the thyra- 49 that is adapted toconvert low-power voltages supplied from a remote point into efficient and compact intensity control for lamp or lampbank III. This unit is connected to the same bright bus as the lighting circuit controlled and tothe neutral to Whichall lighting circuits and control units are connected, Unit ,49 is interchangeable for unit 49' and for other control units. They occupy a minimum of space, are readily removed, repaired when necessary, and

installed; and these features facilitate alteration and expansion of any given installation to meet changing lighting requirements. Only one phase of power for ,inputtransformers 48, 48', etc., is required-whether the controlled lighting circuit is connected to bright bus 18 or to bright bus 18.

This flexibility, mentioned previously, is attributable to rectifiers 4B and 42 which not only smooth out the transients impressed on the vacuum-tube grids, but also eliminate phase-reversal difiiculties.

Units 49, 49' and so on include the thy-ratrons which pass lighting currentsthat are heavy, and

.for this reason the units are located near the lighting center, assembled in a rack in any available space. The operator is stationed at any convenientpoint where the lighting effects can be viewed directly, remote from the bank of control units. Between the operators position and. the control bank there is a cable including a pair of low-current power lines and a large number of control lines to transformers 48, 48, etc.

Two adjustable networks are available to the operator. Both networksare energized by stepdown autotransformer 50, connected between one input terminal of autotransformer l2 and neutral. .Both networks are useful in a single installation for different purposes. The networks are similar in that they both include a master potentiometer and at least one group of potentiometers individual to each lighting bank over which separate control is or may be desired.

The simpler control network of the two is termed the Individual proportional master, A variable autotransformer 52, used as the master potentiometer, is connected at its input terminals to autotransformer 5B and has a series of individual potentiometers 54, 54, etc., connected at their input terminals to the adjustable output portion 56 of the master potentiometen An individual potentiometer is providedfor each lightingbank H3, H3, etc. The power required of each potentiometer 54 is very low, only enough to energizeone verysmall transformerAB and its rectifier and negative-grid load. Consequently the individual potentiometers can be miniature sliding-tap resistors so inexpensive and readily available. The output portion ofeachindividual potentiometer is connected through a double-pole double-throw transfer switch 58, through the-connecting cable, to its respective inputtransformer in unit .49, v 19, etc. When the individual proportional master is operated, through its master potentiometer-52, all of the light banks are varied between darkness and the several brightnessjimits as fixed by the several individual; potentiometers. This variation is uniform and proportional; no light bank reaches its maximum intensity before the others. In the operators booth the individual potentiometers are arranged for easy access, so that an individual light bank can be readily adjusted as circumstance may demand without affecting the others.

The other control network for units 49 is termed the Fader and is energized by the same ,autotransformer 58 that supplies thefirst control network. It includes sliding-tap autotransformerfiil as its master potentiometer, having adjustable complemental portions 62 and 64. The

latter portion is on the neutral side of the fixedvoltage supply line. The primary winding of unity-ratio transformer 58 is connected across output portion 52 of master 6G, and onev of its secondary terminals is grounded. Aseries of miniature sliding-tap resistors a, 101), 10c, etc., termed preset potentiometers or simply presets, is connected across the secondary of transformer 66. A second series of presets 12a, 72b, -'l2c, etc. is connected across the grounded output portion 64 of master potentiometer 60. A selector-swit0h deck 74, having contacts Ma, Mb, lac, etc.,.is.arranged to connect any selected slide contact of presets 10 through transfer switch 58 to one input terminal of unit 49. Similarly, another selectorswitch deck 76 having contacts 16a, 76b, 16c, etc., is arranged to connect any selected slide contact of presets 12 through transfer switch 58 to the other input terminal of unit 4%. The output portions of presets Iii andflz are thus connected in series to energize unit 49, and their junction is grounded. This symmetry of the presets about neutral or ground is a factor promoting safety and facilitating construction, and is the controllin reason for including the unity-ratio transformer.

The phasing oftransformer 66 is such that its output is series-aiding with respect to the output of portion 64 of master potentiometer 5E]. The voltage across presets 79 and 12 in series thus remains constant at the terminal voltage of master .60 regardless of the position of its slide contact,

the internal voltage drops in parts 66 and 66 be ing disregarded as negligible. By moving the slideof master 60 from one extreme to the other, the terminal voltage of the master can be shifted from the selected preset 'm to the selected preset l2 and reversely. One preset or the other remains in the circuit, to the extent of its output portion, without delivering voltage; but the input impedence of unit 49 is by design so high in relation to the total series resistance of any selected pair of presets (a factor of twenty-five is desirable) that the inclusion of part of the idle preset in the output circuit of the energized preset is of little consequence. The arrangement is of considerable advantage in fading from lighting control by one preset to control'by the other preset of any selected pair 10 and 12. The brightness varies smoothly from the limit determined by the setting of one preset to that fixed by the other preset, with no objectionable dip into darkness. Of course, if darkness were actually required between different levels of intensity, this could be accomplished by setting a preset of one group at zero and shifting from one preset of the other group to the zero preset and then to a second preset of the-first group.

During the times when one preset is effective, the idle one can be adjusted if desired, although this would not be usual. However, switches 14 and 16 are of suchconstruction that at least one pair of their contacts is closed in all positions of adjustment; and with this provision the selector switch of the idle preset can be manipulated for a new selection, sequentially as from position a to b or otherwise, without affecting the lighting control circuit to transformer it. When a new selection has been made, and the scene requiring the effective presets is over, master Ed is operated to render the new selection effective. The preset of any group H! or 12 can be selected while the other group 12 or iii, respectively is in effect; and the presets of that other group can be switched after fading to a preset in the previously idle group.

Additional groups of presets iii and Z2 (including presets lilo, Nib, and 12a, lZb, are connected to the same master 6% and transformer 66 as for presets ill and 12, for controlling unit 49 of lamp bank iii. Corresponding selectorswitch decks M and it are also provided. Switch decks M, M, etc. (one for each lamp bank to be controlled) are mechanically ganged to constitute one selector switch, and switch decks "it, it, etc. are similarly gan god to constitute a second selector switch. It is thereby made possible to fade from one complete array of preset lighting condi tions to another, smoothly and proportionally, simply by manipulation of master potentiometer 6! from one extreme to the other. Selection of a new preset lighting array is achieved simply by operation of either selector switch M, i i, or selector switch it, Iii while the other remains in the circuits of the effective presets. For special effects or in case of emergency it is also possible to switch over to the individual proportional master network by throwin any desired one or group of transfer switches 53. With the aid of a preset array in each selector switch set for darkness, it becomes possible to fade into dark from any given preset selection, transfer to the other network by throwing all transfer switches 58, and then operating its master 52. from zero to maximum. Convenient variation of intensity of any or several light banks individually by means of potentiometers d, 5 etc, is thus enabled. Return to Fader control is achieved smoothly by re turn to darkness using Master 52, reversal of switches 58 with dark presets in efiect, and reverse sweep of master potentiometer iii! to lighting under selected preset conditions. In any given scene it may be required to dim one important lamp bank without affecting the other lighting, and this can be achieved either by fading to another group of presets having appropriate adjustments, or by shifting that lamp bank to the other network for individual variation.

Using the control system described, the lighting requirements of a sequence of dramatic incidents can be preset, and the operator can fade from one to the next smoothly and expeditiously, irrespective of the desired number of lamp banks of differing peak intensities. This control can be duplicated from one performance to the next. The flexibility of control achieved with the presets can be extended by transfer to the individual controls as described, restricting the transfer to only the desired banks. The nature of the control units and their control networks is such that the changes of intensity follow instantly with the operation of the controls, without the electrical and mechanical lags characteristic of known remote-controlled lighting systems. The control networks that may be located far from the heavycurrent lighting circuits are simple, compact and inexpensive. The heavy-current control units 49 are interchangeable, they may be used for all sizes of lamp banks up to the maximum rating of the thyratrons, and the units are of such nature that expansion to meet new lighting requirements is comparatively an easy task. None of the ponderous components and unwieldy controls of previous lighting control systems are required. The system is highly efficient. For the most part it utilizes such small parts as are commonly found in radio receivers; and the thyratrons consume very little power in comparison to the lamps they control, As an indication of scale, Master Bil of one ampere rating can simultaneously supply about 260 presets and their control units.

The foregoing represents a preferred lighting control system illustrating several separately and collectively useful features of my invention, as pointed. out in the appended claims.

What is claimed is:

1. A phase controller for the grid of a gas-type electron-discharge device in series with a lamp energized by an alternating-current source, comprising a voltage divider connected to the source, a grid-controlled vacuum tube and a reactive impedance connected in series and to the terminals of said voltage divider, a coupling circuit between a point intermediate said vacuum tube and said impedance and a tap of said voltage divider for controlling the gas-type device, and a widely adjustable source of controlled voltage for the grid of said vacuum tube.

2. The method of controlling illumination intensity of an alternating-current lamp having a series thyratron, comprising the steps of supplying voltage variable in magnitude in relation to the desired intensity, converting the controlled voltage to a corresponding two-directionally conductive resistance, and deriving therefrom an alterhating-current voltage the phase of which is critically related to that of the lamp circuit for timing the firing of the thyratron appropriately for the desired intensity.

3. A controller for the grid of a gas-type electron-discharge device in series with a lamp energized by an alternating-current source, comprising a voltage divider connected to said source, an electrically variable resistance and an impedance connected in series to the terminals of said voltage divider, and an output circuit for controlling said grid and having input connections between a tap in said voltage divider and the point intermediate said impedance and said variable resistance.

4. A phase-controller for the grid of a gas-type electron-discharge device in series with a lamp energized by an alternating-current source, comprising a voltage divider connected to said source, a back-to-back pair of grid-controlled vacuum tubes, a reactive impedance in a series circuit with said pair of tubes, said series circuit being connected to the terminals of said voltage divider, an output transformer having its primary winding connected to a point between said tubes and said impedance and to a tap of said voltage divider, and an adjustable alternatingwurrent supply for the grids of said vacuum tubes and coupled to the alternating-current source that energizes said voltage divider.

5. A phase-controller according to claim 4, including a dry-disc full-wave rectifier between said adjustable alternating-current supply and each of the grids of said vacuum tubes.

6. An alternating-current circuit including a pair of vacuum tubes each having a cathode, a plate, and a control grid, the cathode of each device being connected to the plate of the other device in back-to-back relation, a widely adjustable alternating-current voltage source, and separate coupling circuits between said source and each of said grids, said circuits including means polarized to drive both grids alike in relation to their cathodes When the related plates are driven positive.

'7. In combination, a variable-intensity lamp, a phase-responsive control circuit for said lamp, a series circuit including a reactive impedance and a back-to-back pair of grid-controlled vacuum tubes, said series circuit being connected to an alternating-current source at its terminals and at an intermediate point to said phase-responsive circuit, and an adjustable control for the grids of said vacuum tubes.

8. In combination, a variable-intensity lamp, a phase-responsive control circuit for said lamp, a

series circuit including a reactive impedance and a back-to-back pair of grid-controlled vacuum tubes, said series circuit being connected at its terminals to an alternating current source and at a point intermediate said impedance and said vacuum tubes to said phase-responsive control circuit, a rectified alternating-current supply for controlling said vacuum tubes, and a potentiometer for controlling the input to said supply.

9. In combination, a variable-intensity lamp, a phase-responsive control circuit for said lamp, and a variable phase-shift circuit for said control circuit, said phase-shift circuit including a vacuum tube the internal resistance of which is variable as a function of the applied control voltage, and an individual potentiometer and a master potentiometer arranged in cascade to control said vacuum tube, the illumination intensity being variable by said master potentiometer up to the limit fixed by said individual potentiometer.

10. In combination, an array of variable-intensity lamps, a phase-responsive control circuit for each lamp, a phase-shifting network for each control circuit including a vacuum tube the internal resistance of which is variable as a function of the applied control voltage, a control circult for each of said phase-shifting networks including a preset potentiometer, and a master potentiometer for gradually intensifyin the illumination of said array of lamps to limits severally fixed by said preset potentiometers.

11. In combination, a variable-intensity lamp, a phase-responsive control circuit for said lamp, a phase-shifting network for said control network including a vacuum tube the internal resistance of which is variable as a function of the applied control voltage, and an adjustable source of control voltage for said vacuum tube including a master potentiometer having an adjustable tap and a pair of preset potentiomcters having their output sections coupled to said vacuum tube and their input terminals coupled to the sections of said master potentiometer on opposite sides of said tap, whereby adjustment of said master potentiometer from one extreme to the opposite adjusts the lamp from a maximum fixed by one of said preset potentiometers to a maximum fixed by the other of said preset potentiometers.

12. In combination, a variable-intensity lamp, a phase responsive control circuit for said lamp, a phase-shifting network for said control circuit including a vacuum tube the internal resistance of which varies as a function of the applied control voltage, and a variable voltage supply unit including a pair of preset potentiometers having their output sections connected in series and coupled in control relation to said vacuum tube, a master potentiometer having an adjustable tap, and an isolating unit, the portions of said master potentiometer on opposite sides of said tap being connected, respectively, to the input end of said isolating malt and to the terminals of one of said preset potentiometers, the output end of said isolating unit being connected to the terminals of the other of said preset potentiometers.

13. In combination, a variable-intensity lamp, 2. control unit for said lamp, a pair of preset potentiometers having their output sections connected in a closed loop including the input portion of said control unit, a master potentiometer having an adjustable tap spanned on one portion by one of said preset potentiometers, an isolating unit having its input end spanned by the other portion of said master potentiometer and its output end spanned by the other of said preset potentiometers, said isolating unit being so phased that adjustment of said master potentiometer from one extreme to the opposite extreme will cause variation of the intensity of said lamp from by one of said preset 14. In combination, an array of variable-intensity lamps, a control unit for each of said lamps, a plurality of pairs of preset potentiometers, said pairs having output portions conthe terminals of one preset potentiometer of each pair and the other section of said master potentiometer being coupled to the terminals of the others of said pairs of preset potentiometer-s, whereby adjustment of said master potentiometer from one extreme to the opposite extreme will cause said lamps to fade from their bright limits as fixed severally by onepreset potentiometer of the pairs proportionally to the several limits fixed by the other preset potentiometers in the respec tive pairs.

15. In combination, ,an array of variable-im tensity lamps. a control unit for each lamp, a plurality of preset potentiometers for each unit, a pair of selector switches each having multiple ganged sections corresponding to the number of control units and arranged to connect said pre set potentiometers tosaid units in pairs, and a master potentiometer having complemental portions, the preset potentiometers of one of said selector switches being coupled to one of said portions and the preset potentiometers of the other of said selector switches being coupled to the other of said portions, whereby the illumination intensities of the lamps can be changed from the several limits fixed by the selected preset potentiometers of One of said switches to the several limits fixed by the selected preset potentiometers of the other of said switches by operating said master potentiometer from one extreme to the other.

16. An arrangement for applying alternating current from a source to a load comprising a master potentiometer having complemental sections, a transformer having its primary connected across one of said sections, a preset potentiometer connected across the other of said sections, another preset potentiometer connected across the secondary of said transformer, the output portions of the preset potentiometers being connectedin series across the load and so phased by the transformer as to be series-aiding when said master potentiometer is in any intermediate position of adjustment, the junction of said preset potentiometers being joined to a fixed terminal of said. master potentiometer.

17. The combination of the arrangement of claim 16 with a load spanning said series portions of said preset potentiometers, the impedance of the load being at least ten times that of either preset potentiometer.

18. A phase control network comprising a voltage divider, a series circuit including a pair of vacuum tubes connected back-to-back so that one tube is conductive during each half an alternating-current cycle of applied voltage, said pair of tubes being connected in series with a reactive impedance across said voltage divider, an output circuit connected to a tap in said voltage divider and to a point in said series circuit between said vacuum tubes and said impedance, and a variable control for said vacuum tubes.

19. A phase shifter comprising a voltage divider, a series circuit including a vacuum tube and a reactive impedance connected across said voltage divider, an output circuit connected to a tap in said voltage divider and to a point in said series circuit between said vacuum tube and said impedance, and a variable control circuit for said vacuum tube including a full-wave rectifier and a potentiometer, said variable control and said voltage divider having common supply connections.

20. In combination with a gas-type electrondischarge device having a control grid, an alternating-current control circuit comprising a condenser connected in a series circuit with a pair of grid-controlled vacuum tubes, said tubes being arranged in parallel circuits and oppositely polarized for full-cycle conductivity, a control circuit for said vacuum tubes, and a coupling circuit between the grid of the gas-type electron-discharge device and a point in said series circuit between said condenser and said tubes.

21. A lighting control circuit comprising a pair of gas-type tubes connected together in a manner to-provide a current path during successive halves of an alternating-current cycle and having control electrodes, a series circuit including a condenser and a back-to-back pair of vacuum tubes having control grids, a transformer having two secondary windings connected respectively to said control electrodes and having a primary winding connected to said series circuit, and a variable control circuit connected to said grids.

22. A lighting control circuit comprising a pair of gas-type tubes connected together in a manner to provide a current path during successive halves of an alternating-current cycle and having control electrodes, a series circuit including a reactive impedance and a parallel pair of reversely polarized variable resistance devices each being substantially non-conducting in one direction and having a control element for varying the resistance, a coupling circuit between the control electrodes of said gas-type tubes and a point in said series circuit between said reactive impedance and said parallel devices, and an adjustable control circuit connected to said elements.

23. A variable-intensity lighting system comprising a lamp, a back-to-back pair of thyratrons in a series circuit with said lamp, said series circuit having terminals for energization by an alternating-crurent source, and a network con-- nected in control relation to said thyratrons including a pair of vacuum tubes connected to said Cir terminals for coordinated energization with said thyratrons, each of said vacuum tubes including a grid, a cathode, and a plate, and having variable grid-control means, the plate of one of said tubes being joined directly to the cathode of the other of said tubes in back-to-back relation.

24. A control circuit for a variable-intensity lighting system including a grid-controlled gastype tube connected in a circuit to alternatingcurrent supply terminals and a phasing circuit connected to the grid of said tube including a condenser and a pair of unidirectionally conductive devices connected to said condenser providing charging and discharging paths, at least one of said devices having a control element adapted to impart a variable-resistance characteristic, and a control circuit connected to said control element.

25. A phase-control network comprising a condenser and a pair of vacuum tubes connected in series to alternating-current terminals, each of said tubes having a plate, a cathode, and a control grid, the plate-cathode spaces of said tubes being connected in parallel circuits and the plate of one of said tubes being connected to the cathode of the other, and an adjustable voltage-supply for said control grids.

26. A controlled lighting circuit having power supply terminals for alternating-current energization, comprising a lamp load and a back-toback pair of thyratrons joined in series and connected to said terminals, a voltage-responsive phasing circuit coupled through a two-secondary transformer in control relation to said thyratrons, said phasing circuit including a series-connected condenser and. back-to-back pair of vacuum tubes, each tube having a control grid, a variable voltage supply including a transformer having a pair of secondary windings connected through rectifiers to said control grids in such polarity as to drive said grids negative, a potentiometer in said variable voltage supply having an adjustable output section connected to said transformer and having fixed terminals, and a variable voltage divider having an adjustable output section connected to said fixed terminals, said variable voltage divider and said phasing circuit having stable connection to said power supply terminals.

27. A controlled lighting array having a variable voltage divider and a plurality of lamp loads, phasing circuits, and variable voltage supplies in accordance with claim 26, the adjustable output section of said variable voltage divider being connected to the terminals of the potentiometers in said variable voltage supplies.

28. A controlled lighting array in accordance with claim 2'7 wherein said power supply terminals are separated from said lamp loads by a center-tapped autotransiormer with certain of said lamp-loads connected on one side of the center-tap and the remainder of the lamp l'oads connected on the opposite side of the centertap, said variable voltage divider being connected on one side of the center-tap, and wherein said rectifiers are of the full-wave rectifier type.

29. An alternating-current circuit including a pair of vacuum tubes each having a grid, a cathode, and a plate, the plate-cathode spaces of said tubes being connected in parallel circuits with the cathode of one tube connected to the plate of the other, means to apply alternating-current voltage to said parallel circuits, and means to apply unidirectional voltages of like value to the grid-cathode spaces of said tubes.

30. An alternating-current circuit including a 13 pair of vacuum tubes each having a grid, a cathode and a plate, the plate-cathode spaces of said tubes being arranged in parallel circuits, with the cathode of one tube joined to the plate of the other, means to apply alternating-current age on said grid-cathode circuits.

31. A variable-resistance alternating-current circuit comprising a back-to-back pair of reversely polarized unidirectionally conductive and variably resistive devices each having a control electrode, means to impress alternating-current voltage on said back-to-back devices, and means to impress like voltages on said control electrodes during the respective half-cycles of impressed voltage when said devices are conductive.

GEORGE C. IZEN OUR.

14 REFERENCES CITED The following references are of record in the file of this patent:

UNITED STATES PATENTS Number Name Date 1,914,193 Bedford June 13, 1933 2,005,893 Gulliksen June 25, 1935 2,231,955 Shrader Feb. 18, 1941 2,376,392 Shepherd May 22, 1945 2,411,030 Ryder Nov. 12, 1946 FOREIGN PATENTS Number Country Date France Apr. 10, 1933 OTHER REFERENCES Analysis and Characteristics of Vacuum Tube 'I'hyratron Phase-Control Circuit, by Samuel C. 

